KillerZ
Sep30-09, 09:38 AM
1. The problem statement, all variables and given/known data
In the circuit shown, the same current must flow through all three componets as a result of conservation laws. Using the fact that the total power supplied equal the total power absorbed, show that the voltage across resistor R2 is given by:
v_{R_{2}} = v_{s}\frac{R_{2}}{R_{1} + R_{2}}
http://i33.tinypic.com/2d6p6xw.png
2. Relevant equations
p = vi = i^{2}R = \frac{v^{2}}{R}
3. The attempt at a solution
I said:
p_{v_{s}} = p_{R_{1}} + p_{R_{2}}
because power supplied = power absorbed
p_{v_{s}} = p_{R_{1}} + p_{R_{2}}
But I don't think this is right because it would not simplify right.
v_{s}i = i^{2}R_{1} + \frac{v_{R_{2}}^{2}}{R_{2}}
In the circuit shown, the same current must flow through all three componets as a result of conservation laws. Using the fact that the total power supplied equal the total power absorbed, show that the voltage across resistor R2 is given by:
v_{R_{2}} = v_{s}\frac{R_{2}}{R_{1} + R_{2}}
http://i33.tinypic.com/2d6p6xw.png
2. Relevant equations
p = vi = i^{2}R = \frac{v^{2}}{R}
3. The attempt at a solution
I said:
p_{v_{s}} = p_{R_{1}} + p_{R_{2}}
because power supplied = power absorbed
p_{v_{s}} = p_{R_{1}} + p_{R_{2}}
But I don't think this is right because it would not simplify right.
v_{s}i = i^{2}R_{1} + \frac{v_{R_{2}}^{2}}{R_{2}}